JP6334437B2 - Lighting device - Google Patents

Description

  The present invention relates to a lighting device.

  In general, lighting devices are provided in various forms such as a direct ceiling light, a landscape lighting, a sleeping lamp, and a stand depending on the application. Such an illuminating device must be lit at a sufficient luminance level depending on the purpose. For this reason, in recent years, light emitting diodes (LEDs) have been used in lighting devices. Light emitting diodes have the advantages of low power consumption, semi-permanent lifetime, fast response speed, safety, and environmental compatibility compared with existing light sources such as fluorescent lamps and incandescent lamps. Therefore, research for replacing the existing light source with a light emitting diode is underway.

  However, the lighting device as described above is turned on / off by a switch connected by wire. For this reason, the user of the illuminating device has been troublesome to control the illuminating device.

  Accordingly, an object of the present invention is to provide an illumination device that can be easily controlled.

  A lighting device according to the present invention for solving the problem includes a control module that supplies power, a heat radiating body that houses the control module, a light source that is attached to the heat radiating body and is connected to the control module, and is inserted into the heat radiating body. And a communication module having a connection terminal connected to the control module and an antenna element protruding from the radiator.

  The lighting device according to the present invention has a wireless communication function. At this time, the lighting device can receive a wireless control signal via the communication module. And the illuminating device can control a light source with a wireless control signal. This enables wireless control of the lighting device. That is, the user of the lighting device can easily control the lighting device. This improves the convenience of the user who uses the lighting device.

It is a perspective view which decomposes | disassembles and shows the illuminating device by the Example of this invention. It is a perspective view which shows the coupling | bonding structure of the illuminating device by the Example of this invention. In FIG. 1, it is a perspective view which decomposes | disassembles and shows a communication module. In FIG. 1, it is sectional drawing which shows the cross section cut | disconnected along А-А '.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the accompanying drawings, the same components are denoted by the same reference numerals as much as possible. Detailed descriptions of known functions and configurations that obscure the gist of the present invention will be omitted.

  In the following description, when it is stated that each component is formed “above” or “below” another component, “above” and “below” are “direct” or “other configurations”. Includes everything formed "indirectly". In addition, the reference to the top or bottom of each component will be described based on the top and bottom of the drawing.

  FIG. 1 is an exploded perspective view illustrating a lighting device according to an embodiment of the present invention, and FIG. 2 is a perspective view illustrating a coupling structure of the lighting device according to the embodiment of the present invention. FIG. 3 is an exploded perspective view showing the communication module in FIG. 4 is a cross-sectional view showing a cross section taken along А-А 'in FIG.

  1 to 4, the illumination device 100 according to the present embodiment includes a light source 110, a light source coupling unit 120, a back cover, a control module 140, a housing 150, a blocking cover 160, and a power supply cover 170. The radiator 180 and the communication module 190 are included.

  The light source 110 generates light. Here, the light source 110 may be a light emitting diode. Such a light source 110 includes a power feeding element 111, a plurality of power feeding wires 113, a plurality of base substrates 115, and a plurality of light emitting diode elements 117.

  The power feeding element 111 supplies power from the light source 110. Here, the power feeding element 111 may be a printed circuit board (PCB).

  The power supply wire 113 connects the power supply element 111 and the base substrate 115. At this time, the power supply wire 113 can directly connect the power supply element 111 and each base substrate 115. Alternatively, the power supply wire 113 can connect the power supply element 111 and a part of the base substrate 115 to interconnect the base substrate 115. The power supply wire 113 transmits power from the power supply element 111 to the base substrate 115.

  The base substrate 115 controls driving of the light source 110. At this time, the base substrate 115 applies the power of the power feeding element 111 to the light emitting diode. Here, the base substrate 115 may be a printed circuit board.

  The light emitting diode element 117 is mounted on the base substrate 115. At this time, a plurality of light emitting diode elements 117 can be mounted on each base substrate 115. The light emitting diode element 117 generates light by power applied from the base substrate 115. That is, the light emitting diode element 117 outputs light.

  The light source coupling unit 120 is coupled to the light source 110 and fixes the light source 110. At this time, at least one first coupling hole 121 and at least one second coupling hole 123 are formed in the light source coupling unit 120. The first coupling hole 121 accommodates the base substrate 115. Here, the light source coupling unit 120 fixes the base substrate 115 and the light emitting diode element 117 at the position of the first coupling hole 121. Then, the light source coupling unit 120 exposes the light emitting diode element 117 through the first coupling hole 121. Further, the second coupling hole 123 accommodates the power feeding element 111 and the communication module 190. Further, the light source coupling unit 120 exposes the power feeding element 111 and the communication module 190 through the second coupling hole 123. Here, the second coupling hole 123 allows the communication module 190 to pass therethrough. That is, the second coupling hole 123 projects the communication module 190 in both directions with the light source coupling unit 120 as a boundary. Here, the light source coupling unit 120 may be formed of an insulator.

  The back cover surrounds the light source 110 on the light source coupling unit 120. Here, the back cover may have a bulb shape in which an opening is formed. The back cover protects the light source 110 and emits light from the light source 110. At this time, the back cover distributes light on the front surface or the back surface of the lighting device 100. Here, the back cover can be formed of at least one of glass, plastic, polypropylene, and polyethylene. Alternatively, the back cover may be formed of polycarbonate having excellent light resistance, heat resistance, and impact strength characteristics. In the back cover, a milky white paint may be coated on the inner surface facing the light source 110. The paint may include a diffusing material for diffusing light.

  The control module 140 controls the overall operation of the lighting device 100. At this time, although not shown, the control module 140 may include a main board and a plurality of components. The main board may be a printed circuit board. The component is mounted on the main board and electrically connected to the main board. These components include a conversion unit and a drive unit. The conversion unit is connected to an external power supply via the main board. Then, the conversion unit converts the AC power source of the external power source into a DC power source. The driving unit controls driving of the light source 110.

  The control module 140 supplies power to the light source 110. Here, the control module 140 may be a power supply unit (PSU). At this time, the control module 140 can control the light source 110 by a wireless control signal received from the communication module 190. Such a control module 140 includes a power supply terminal 141 and a coupling terminal 143.

  The power supply terminal 141 is connected to the light source 110. Such a power supply terminal 141 is in contact with the power supply element 111 of the light source 110. At this time, the power supply terminal 141 protrudes from the control module 140. Here, the power supply terminal 141 is coupled to the main board and protrudes from the main board. The power supply terminal 141 faces the power supply element 111.

  The power supply terminal 141 supplies power to the light source 110. That is, the control module 140 supplies power to the light source 110 through the power feeding element 111. The power supply terminal 141 transmits a light source control signal for controlling the light source 110 to the light source 110. That is, the control module 140 transmits a light source control signal to the light source 110 via the power feeding element 111.

  The coupling terminal 143 is connected to the communication module 190. Such a coupling terminal 143 is coupled to the communication module 190. At this time, the coupling terminal 143 may protrude from the control module 140. Here, the coupling terminal 143 is coupled to the main substrate and protrudes from the main substrate. The coupling terminal 143 can accommodate the communication module 190. Here, the coupling groove 145 may be formed in the coupling terminal 143. The coupling groove 145 may face the communication module 190. Further, the coupling groove 145 may accommodate the communication module 190.

  The housing 150 accommodates the control module 140. A housing hole 151 is formed in such a housing 150. That is, the housing 150 accommodates the control module 140 through the accommodation hole 151. At this time, the housing 150 may be formed in a cylindrical shape. The housing 150 can prevent an electrical short between the control module 140 and the heat radiating body 180. Here, the housing 150 may be formed of a material excellent in insulation and durability. The housing 150 may be formed of a resin material.

  The housing 150 includes a connection terminal 153. At this time, the housing 150 is fixed to an external power source via the connection terminal 153. Here, the connection terminal 153 may be fixed to an external power source by a socket method. Further, the connection terminal 153 can be connected to an external power source. That is, the connection terminal 153 can be electrically connected to an external power source. Furthermore, the connection terminal 153 can electrically connect the control module 140 and an external power source. Here, the connection terminal 153 may be made of a conductive material.

  The blocking cover 160 seals the housing 150. Such a blocking cover 160 covers the accommodation hole 151 of the housing 150 from above. At this time, the blocking cover 160 can prevent an electrical short between the control module 140 and the heat radiating body 180. Here, the blocking cover 160 may be formed of a material that is excellent in insulation and durability. The blocking cover 160 may be formed of a resin material.

  In addition, at least one through hole 161 is formed in the blocking cover 160. The through hole 161 is disposed on the same axis as the second coupling hole 123. The through hole 161 accommodates the power supply terminal 141 and the communication module 190. At this time, the through hole 161 allows the power supply terminal 141 and the communication module 190 to pass therethrough. Here, the blocking cover 160 exposes the power supply terminal 141 and the coupling terminal 143 through the through hole 161. That is, the through hole 161 projects the power supply terminal 141 toward the power supply element 111. In addition, the through hole 161 projects the communication module 190 toward the coupling terminal 143.

  The power supply cover 170 seals the housing 150. Such a power supply cover 170 covers the accommodation hole of the housing 150 from below. The power supply cover 170 is in contact with an external power source. At this time, the power supply cover 170 electrically connects the control module 140 and an external power source. Here, the power supply cover 170 may be made of a conductive material.

  The radiator 180 accommodates the control module 140, the housing 150, and the blocking cover 160. An accommodation groove (not shown) is formed in such a heat radiating body 180. That is, the radiator 180 accommodates the control module 140, the housing 150, and the blocking cover 160 by the accommodation groove. Then, the light source 110 is attached to the radiator 180. Further, the radiator 180 dissipates heat generated by the light source 110 and protects the control module 140 from the heat generated by the light source 110. At this time, the radiator 180 includes a first radiator 181 and a second radiator 185.

  The first heat radiating body 181 is disposed on the blocking cover 160. Such a first radiator 181 is coupled to the back cover. At this time, the first heat radiating body 181 is fixed to the back cover at the edge. Then, the light source 110 and the light source coupling unit 120 are mounted on the first heat radiator 181. Such a first radiator 181 is in contact with the light source 110. At this time, the first radiator 181 moves the heat generated by the light source 110 to the second radiator 185. Here, the first heat radiating body 181 is formed in a circular shape. Further, the first heat radiating body 181 can be formed in a plane.

  In addition, at least one insertion hole 183 is formed in the first heat radiator 181. The insertion hole 183 is disposed on the same axis as the second coupling hole 123 and the through hole 161. The insertion hole 183 accommodates the power supply terminal 141 and the communication module 190. At this time, the insertion hole 183 allows the power supply terminal 141 and the communication module 190 to pass therethrough. Here, the first heat radiator 181 exposes the power supply terminal 141 and the coupling terminal 143 through the insertion hole 183. That is, the insertion hole 183 projects the power supply terminal 141 toward the power supply element 111. Further, the insertion hole 183 projects the communication module 190 toward the coupling terminal 143.

  The second heat radiator 185 surrounds the housing 150. At this time, the second radiator 185 exposes the connection terminal 153. That is, the second heat radiator 185 surrounds a portion of the housing 150 excluding the connection terminal 153. Here, the second radiator 185 can be formed in a cylindrical shape. Such a second radiator 185 extends downward from the first radiator 181. At this time, the second heat radiating body 185 dissipates heat generated by the light source 110. Here, the diameter of the second radiator 185 may decrease as it extends downward along the central axis of the first radiator 181.

  The second heat radiating body 185 includes a plurality of heat radiating pins 187. At this time, the surface area is increased by the second heat dissipating body 185 including the heat dissipating pins 187. The heat dissipation pin 187 extends downward from the first heat dissipation body 181. At this time, the heat radiation pins 187 may be arranged radially from the central axis of the first heat radiator 181. Here, the heat dissipation pin 187 protrudes in a direction perpendicular to the central axis of the first heat dissipation body 181.

  The communication module 190 receives a wireless control signal for controlling the lighting device 100. At this time, the communication module 190 is connected to the control module 140. Here, the communication module 190 is separated from the light source 110 and crosses the light source coupling unit 120, the radiator 180, and the blocking cover 160. Communication module 190 is coupled to control module 140. Such a communication module 190 includes a substrate 210, a connection terminal 220, a grounding unit 230, an antenna element 240, and a protective cover 250.

  The substrate 210 is provided for support in the communication module 190. At this time, the substrate 210 has a flat plate structure. Here, the substrate 210 may be a printed circuit board. The substrate 210 can include a dielectric. Such a substrate 210 includes a connection region 211, a drive region 213, and an antenna region 215.

  The connection region 211 is located at one end of the substrate 210. Such a connection area 211 faces the control module 140. At this time, the connection region 211 faces the coupling terminal 143. Here, the connection region 211 may face the coupling groove 145. Then, the connection region 211 is inserted into the heat radiating body 180. At this time, the connection region 211 is accommodated in the accommodation groove of the heat radiating body 180. The connection area 211 is coupled to the control module 140. At this time, the connection region 211 is fixed to the coupling terminal 143. Here, the connection region 211 can be inserted into the coupling groove 145.

  The drive area 213 extends from the connection area 211. At this time, the drive region 213 is located at the center of the substrate 210. Such a driving region 213 crosses the light source coupling unit 120, the heat radiator 180, and the blocking cover 160. The drive region 213 is inserted into the heat radiating body 180. At this time, the drive region 213 is accommodated in the second coupling hole 123 on the same axis, the insertion hole 183, the through hole 161, and the accommodation groove of the radiator 180.

  The drive region 213 includes a drive element (not shown). At this time, the drive element is inherent in the substrate 210 and disposed in the drive region 213. Here, the drive element extends from the drive region 213. One end of the drive element extends to the connection region 211 and the other end extends to the antenna region 215.

  The antenna region 215 is located at the other end of the substrate 210. Here, the antenna region 215 is located on the opposite side of the connection region 211 with the drive region 213 as a boundary. The antenna area 215 is connected to the connection area 211 via the drive area 213. Such an antenna region 215 protrudes from the radiator 180. Here, the antenna region 215 is exposed from the radiator 180. At this time, the antenna region 215 is located on the light source coupling unit 120. Here, the antenna region 215 may be separated from the light source 110.

  The connection terminal 220 is provided in the communication module 190 for an interface with the control module 140. Such connection terminals 220 are arranged in the connection region 211 of the substrate 210. At this time, the connection terminal 220 is connected to one end of the drive element. The connection terminal 220 is connected to the control module 140. At this time, the connection terminal 220 is fixed to the coupling terminal 143 together with the connection region 211 and connected to the coupling terminal 143. Here, the connection terminal 220 can be inserted into the coupling groove 145. In addition, power is supplied to the communication module 190 via the connection terminal 220. That is, power is supplied from the coupling terminal 143 to the connection terminal 220.

  The grounding unit 230 is provided for grounding in the communication module 190. Such a grounding portion 230 is disposed in the connection region 211 of the substrate 210. At this time, the grounding unit 230 may be separated from the connection terminal 220. That is, the grounding unit 230 may not contact the connection terminal 220. The grounding unit 230 can be connected to one end of the driving element.

  The antenna element 240 provides a wireless communication function in the communication module 190. At this time, the antenna element 240 resonates in a predetermined frequency band and transmits and receives electromagnetic waves. Here, the antenna element 240 resonates with a predetermined impedance. Such an antenna element 240 is disposed in the antenna region 215 of the substrate 210. At this time, the antenna element 240 is connected to the other end of the drive element. That is, the antenna element 240 is connected to the connection terminal 220 via the drive element. Here, the antenna element 240 may be connected to the grounding part 230 via a drive element. Then, one end of the antenna element 240 is connected to the drive element, and the other end is opened.

  The antenna element 240 protrudes from the heat radiating body 180. Here, the antenna element 240 is disposed outside the radiator 180. That is, the antenna element 240 is exposed from the radiator 180 together with the antenna region 215. Further, the antenna element 240 is separated from the radiator 180. Here, the separation distance (d) between the antenna element 240 and the radiator 180 is approximately 1 mm or more. At this time, the antenna element 240 is positioned on the light source coupling unit 120. Here, the antenna element 240 may be separated from the light source 110.

  The antenna element 240 is driven using the power supplied from the connection terminal 220. At this time, the antenna element 240 receives a radio control signal for controlling the control module 140. Then, the antenna element 240 transmits a radio control signal to the control module 140. At this time, the antenna element 240 transmits a radio control signal to the control module 140 via the connection terminal 220.

  At this time, the antenna element 240 is formed in a patch type and then attached to the antenna region 215. Alternatively, the antenna element 240 is formed in the antenna region 215 by drawing with conductive ink. Alternatively, the antenna element 240 may be patterned in the antenna region 215. Here, the antenna element 240 may be formed in at least one of a bar shape, a meander shape, a spiral shape, a step shape, and a loop shape. The antenna element 240 may be made of a conductive material. Here, the antenna element 240 may include at least one of silver (Ag), palladium (Pd), platinum (Pt), copper (Cu), gold (Au), and nickel (Ni).

  The protective cover 250 accommodates the substrate 210. At this time, the protective cover 250 covers the substrate 210. Here, the protective cover 250 covers the drive region 213 and the antenna region 215 and exposes the connection region 211. That is, the protective cover 250 accommodates the antenna element 240 and exposes the connection terminal 220. In other words, the connection terminal 220 protrudes from the protective cover 250. Here, the protective cover 250 may be formed of at least one of plastic, polypropylene, polyethylene, and polycarbonate. Such a protective cover 250 includes a first protective cover 251 and a second protective cover 253.

  The first protective cover 251 surrounds the drive region 213. Such a first protective cover 251 crosses the light source coupling part 120, the radiator 180, and the blocking cover 160 together with the drive region 213. Then, the first protective cover 251 is inserted into the heat radiating body 180. At this time, the first protective cover 251 is accommodated in the second coupling hole 123 on the same axis, the insertion hole 183, the through hole 161, and the accommodation groove of the radiator 180.

  The second protective cover 253 accommodates the antenna region 215. The second protective cover 253 accommodates the antenna element 240. Here, the second protective cover 253 extends from the first protective cover 251. At this time, an insertion groove is formed in the second protective cover 253. That is, the second protective cover 253 accommodates the antenna element 240 together with the antenna region 215 via the insertion groove.

  The second protective cover 253 protrudes from the heat radiating body 180. Here, the second protective cover 253 is exposed from the radiator 180. At this time, the second protective cover 253 separates the antenna element 240 from the radiator 180. Here, the second protective cover 253 is positioned on the light source coupling unit 120. The second protective cover 253 is fixed to the heat radiating body 180. At this time, the second protective cover 253 is formed in a size larger than the insertion hole 183 so as not to be inserted into the radiator 180.

  According to the present invention, the lighting device 100 has a wireless communication function. At this time, the lighting device 100 can receive a wireless control signal via the communication module 190. And the illuminating device 100 can control the light source 110 with a wireless control signal. Thereby, the wireless control of the lighting device 100 is possible. That is, the user who uses the illuminating device 100 can control the illuminating device 100 easily. Thereby, the convenience of the user who uses the illuminating device 100 improves.

  The embodiments of the present invention disclosed in this specification and the drawings are merely provided as specific examples in order to easily explain the technical contents of the present invention and to help understand the present invention. It is not meant to limit the range. That is, it is obvious to those having ordinary knowledge in the technical field to which the present invention pertains that other variations based on the technical idea of the present invention can be implemented.

DESCRIPTION OF SYMBOLS 100 Illuminating device 110 Light source 111, 141 Feed element 113 Feed wire 115 Base board 117 Light emitting diode element 120 Light source coupling part 121, 123 Joint hole 140 Control module 143 Joint terminal 145 Joint groove 150 Housing 153 Connection terminal 160 Blocking cover 161 Through-hole 170 Power supply cover 180, 181, 185 Radiator 183 Insertion hole 187 Radiation pin 190 Communication module 210 Substrate 211 Connection area 220 Connection terminal 230 Grounding part 240 Antenna element 250, 251, 253 Protective cover

Claims (7)

A control module for supplying power;
A radiator that houses the control module;
A light source mounted on the radiator and connected to the control module;
From the connection terminal inserted into the radiator and connected to the control module, the antenna element protruding from the radiator, the connection terminal and the antenna element connected, and the drive element driving the antenna element, from the connection terminal A communication module having a grounding portion that is spaced apart and in contact with the antenna element via the drive element; and a substrate on which the connection terminal and the antenna element are disposed;
Including a lighting device.   The lighting device according to claim 1, wherein the antenna element is separated from the heat radiator.   The lighting device according to claim 2, wherein the communication module further includes a protective cover that covers the substrate, accommodates the antenna element, and exposes the connection terminal. The substrate is
A connection region in which the connection terminals are disposed;
An antenna region in which the antenna element is disposed;
The lighting device according to claim 3, further comprising: a drive region interposed between the connection region and the antenna region, wherein the drive element is disposed. The protective cover is
A first protective cover inserted into the radiator;
A second protective cover fixed to the radiator and protruding from the radiator;
The lighting device according to claim 4, comprising: The control module is
A coupling terminal to which the connection terminal is coupled and connected;
A power supply terminal connected to the light source;
The lighting device according to claim 1, comprising:   The lighting device according to claim 1, wherein the heat dissipating body has an insertion hole through which the substrate passes.

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